Project description:The epithelial-mesenchymal transition (EMT) is a developmental program that is co-opted by tumor cells to aid in their embarking on the metastatic cascade. Tumor cells that undergo EMT are known to be endowed by, amongst other traits, heightened resistance to chemotherapy. Despite a clear understanding of the role played by the EMT program in conferring cells with these aggressive traits, there are currently no therapeutic avenues specifically targeting the program. Here we show that treatment of mesenchymal-like breast cancer cells with eribulin, an FDA-approved drug for the treatment of advanced breast cancers, leads to a mesenchymal-epithelial transition (MET), accompanied by a loss of metastatic propensity and sensitization of tumor cells to subsequent rounds of chemotherapy. We uncover a novel alternate mechanism of action that provides evidence for eribulin pretreatment as a viable clinical mechanism of MET induction that curtails metastatic progression and the evolution of therapy resistance.

Project description:The epithelial-mesenchymal transition (EMT) is a developmental program that is co-opted by tumor cells to aid in their embarking on the metastatic cascade. Tumor cells that undergo EMT are known to be endowed by, amongst other traits, heightened resistance to chemotherapy. Despite a clear understanding of the role played by the EMT program in conferring cells with these aggressive traits, there are currently no therapeutic avenues specifically targeting the program. Here we show that treatment of mesenchymal-like breast cancer cells with eribulin, an FDA-approved drug for the treatment of advanced breast cancers, leads to a mesenchymal-epithelial transition (MET), accompanied by a loss of metastatic propensity and sensitization of tumor cells to subsequent rounds of chemotherapy. We uncover a novel alternate mechanism of action that provides evidence for eribulin pretreatment as a viable clinical mechanism of MET induction that curtails metastatic progression and the evolution of therapy resistance.

Project description:The epithelial-mesenchymal transition (EMT) is a developmental program that is co-opted by tumor cells to aid in their embarking on the metastatic cascade. Tumor cells that undergo EMT are known to be endowed by, amongst other traits, heightened resistance to chemotherapy. Despite a clear understanding of the role played by the EMT program in conferring cells with these aggressive traits, there are currently no therapeutic avenues specifically targeting the program. Here we show that treatment of mesenchymal-like breast cancer cells with eribulin, an FDA-approved drug for the treatment of advanced breast cancers, leads to a mesenchymal-epithelial transition (MET), accompanied by a loss of metastatic propensity and sensitization of tumor cells to subsequent rounds of chemotherapy. We uncover a novel alternate mechanism of action that provides evidence for eribulin pretreatment as a viable clinical mechanism of MET induction that curtails metastatic progression and the evolution of therapy resistance.

Project description:The epithelial-mesenchymal transition (EMT) is a developmental program that is co-opted by tumor cells to aid in their embarking on the metastatic cascade. Tumor cells that undergo EMT are known to be endowed by, amongst other traits, heightened resistance to chemotherapy. Despite a clear understanding of the role played by the EMT program in conferring cells with these aggressive traits, there are currently no therapeutic avenues specifically targeting the program. Here we show that treatment of mesenchymal-like breast cancer cells with eribulin, an FDA-approved drug for the treatment of advanced breast cancers, leads to a mesenchymal-epithelial transition (MET), accompanied by a loss of metastatic propensity and sensitization of tumor cells to subsequent rounds of chemotherapy. We uncover a novel alternate mechanism of action that provides evidence for eribulin pretreatment as a viable clinical mechanism of MET induction that curtails metastatic progression and the evolution of therapy resistance.

Project description:The epithelial-mesenchymal transition (EMT) is a developmental program that is co-opted by tumor cells to aid in their embarking on the metastatic cascade. Tumor cells that undergo EMT are known to be endowed by, amongst other traits, heightened resistance to chemotherapy. Despite a clear understanding of the role played by the EMT program in conferring cells with these aggressive traits, there are currently no therapeutic avenues specifically targeting the program. Here we show that treatment of mesenchymal-like breast cancer cells with eribulin, an FDA-approved drug for the treatment of advanced breast cancers, leads to a mesenchymal-epithelial transition (MET), accompanied by a loss of metastatic propensity and sensitization of tumor cells to subsequent rounds of chemotherapy. We uncover a novel alternate mechanism of action that provides evidence for eribulin pretreatment as a viable clinical mechanism of MET induction that curtails metastatic progression and the evolution of therapy resistance.

Project description:How disseminated tumor cells (DTCs) engage specific stromal components in distant organs for survival and outgrowth is a critical but poorly understood step of the metastatic cascade. Previous studies have demonstrated the importance of the epithelial-mesenchymal transition (EMT) in promoting the cancer stem cell properties needed for metastasis initiation, while the reverse process of mesenchymal-epithelial transition (MET) is required for metastatic outgrowth. Here we report that this paradoxical requirement for simultaneous induction of both MET and cancer stem cell traits in DTCs is provided by bone vascular niche E-selectin. Using cell surface alkoxyamine-biotinylation and label-free LC-MS/MS, Glg1 was identified as a top candidate Fut3/Fut6-dependent E-selectin ligand. We functionally validated their involvement in the formation of bone metastasis. These findings provide unique insights into the functional role of E-selectin as a component of the vascular niche criticalfor metastatic colonization in bone.

Project description:Malignant progression in cancer has been associated with the emergence of populations of tumor-initiating cells (TIC) endowed with capabilities for unlimited self-renewal, survival under stress and establishment of distant metastases. Additionally, the acquisition of invasive properties driven by the genetic program known as epithelialmesenchymal transition (EMT) may be an essential step in the evolution of neoplastic cells into fully metastatic populations. A widely accepted paradigm is that EMT potentiates tumor cell self-renewal and metastatic behaviour. Here we describe a cellular model in which a clonal population enriched in TIC expresses a genetic program distinct from a second population with traits of stable EMT, and in which both populations cooperate for enhanced local invasiveness and metastasis. Induction of the TIC-enriched population to undergo EMT by several stimuli or by constitutive overexpression of the transcription factor SNAI1 engaged a mesenchymal program while suppressing the CSC program. This suggests that TIC and EMT, contrary to current paradigms, correspond to alternative states. Furthermore, diffusible factors secreted by the population with EMT traits also induced mesenchymal reprogramming of the population enriched in CSCs. Local invasiveness in vitro and lung colonization in vivo of the TIC-enriched population was enhanced by co-injection with the EMT-trait population, and expanded the range of organs to which it metastasized. Thus, in our model, relatively stable TIC and EMT phenotypes reflect alternative genetic programs expressed by distinct clonal populations. We also suggest that dynamic cooperation between tumor subpopulations displaying either TIC or EMT traits may be a general mechanism driving local invasiveness and metastasis. The complete database comprised the expression measurements of 54 675 genes for PC-3/Mc (n=3) and PC-3/S (n=3)

Project description:This model is an expansion of the Regan2022 - Mechanosensitive EMT model (MODEL2208050001); it includes a TGFβ signaling module and autocrine signaling in mesenchymal cells. The expanded 150-node (630 link) modular model undergoes EMT triggered by biomechanical and growth signaling crosstalk, or by TGFβ. As its predecessor, this model also reproduces the ability of the core EMT transcriptional network to maintain distinct epithelial, hybrid E/M and mesenchymal states, as well as EMT driven by mitogens such as EGF on stiff ECM. We also reproduce the observed lack of stepwise MET, in that our model's dynamics does not pass through the hybrid E/M state during MET. We show that in the absence of strong autocrine signals such as TGFβ (not included in this version), cells cannot maintain their mesenchymal state in the absence of mitogens, on softer matrices, or at high cell density. In contrast, potent autocrine signaling can stabilize the mesenchymal state in all but very dense monolayers on soft ECM. This expanded model also reproduces the inhibitory effects of TGFβ on proliferation and anoikis resistance in mesenchymal cells, as well as its ability to trigger apoptosis on soft ECM vs. EMT on stiff matrices. The model offers several experimentally testable predictions related to the effect of neighbors on partial vs. full EMT, the tug of war between mitosis and the maintenance of migratory hybrid E/M states, as well as cell cycle defects in dynamic, heterogeneous populations of epithelial, hybrid E/M and mesenchymal cells.

Project description:Malignant progression in cancer has been associated with the emergence of populations of tumor-initiating cells (TIC) endowed with capabilities for unlimited self-renewal, survival under stress and establishment of distant metastases. Additionally, the acquisition of invasive properties driven by the genetic program known as epithelialmesenchymal transition (EMT) may be an essential step in the evolution of neoplastic cells into fully metastatic populations. A widely accepted paradigm is that EMT potentiates tumor cell self-renewal and metastatic behaviour. Here we describe a cellular model in which a clonal population enriched in TIC expresses a genetic program distinct from a second population with traits of stable EMT, and in which both populations cooperate for enhanced local invasiveness and metastasis. Induction of the TIC-enriched population to undergo EMT by several stimuli or by constitutive overexpression of the transcription factor SNAI1 engaged a mesenchymal program while suppressing the CSC program. This suggests that TIC and EMT, contrary to current paradigms, correspond to alternative states. Furthermore, diffusible factors secreted by the population with EMT traits also induced mesenchymal reprogramming of the population enriched in CSCs. Local invasiveness in vitro and lung colonization in vivo of the TIC-enriched population was enhanced by co-injection with the EMT-trait population, and expanded the range of organs to which it metastasized. Thus, in our model, relatively stable TIC and EMT phenotypes reflect alternative genetic programs expressed by distinct clonal populations. We also suggest that dynamic cooperation between tumor subpopulations displaying either TIC or EMT traits may be a general mechanism driving local invasiveness and metastasis.

Project description:This file contains a 136-node modular Boolean network model of EMT triggered by biomechanical and growth signaling crosstalk, linked to a published network of epithelial contact inhibition, proliferation, and apoptosis (MODEL2006170001). This model reproduces the ability of the core EMT transcriptional network to maintain distinct epithelial, hybrid E/M and mesenchymal states, as well as EMT driven by mitogens such as EGF on stiff ECM. We also reproduce the observed lack of stepwise MET, in that our model's dynamics does not pass through the hybrid E/M state during MET. We show that in the absence of strong autocrine signals such as TGFβ (not included in this version), cells cannot maintain their mesenchymal state in the absence of mitogens, on softer matrices, or at high cell density.